Machine for molding dough and the like.



L. C. REESE.

MACHINE FOR MOLDING DOUGH AND THE LIKE.

APPLICATION FILED JUNE 19, 1916.

L gfififil Patented May15,1917.

B SHEETSSHEET l.

L. C. REESE. MACHINE FOR MOLDING DOUGH AND THE LIKE. APPLICATION FILED JUNE 19, 1916.

I Patented May 15, 1917.

8 SHEETS-SHEET 2.

I -v i mmmu ifi 7 I 5. :g i, I r 0 o s i Q 0 a q r a WITNESSES'; 5 I INVEN? M% MZL& MM M4,

L. C. REESE.

MACHINE FOR MOLDING DOUGH AND THE LIKE.

APPLICATION FILED JUNE 19. 1916.

1,226,951 Patented May 15, 1917.

8 SHEETS-SHEET 3.

WITNESSES; INVEN TOR;

MZWW L. C. REESE.

MACHINE FOR MOLDING DOUGH AND THE LIKE. APPLICATIQN FILED JUNE 19, 1916- 'L %6,251 Patented May 15, 1917.

a SHEETS-SHEET 4.

o o o, o, [r I O I \0/ .55 t8 /4 w W 13/ t2 t3 2K5 2316 r3 INVENTOR. WZTNESSES:

' QWQ M -L. C. REESE.

MACHINE FOR MOLDING DOUGH AND THELIKE.

APPLICATION FILED JUNE 19, I916.

Patented May 15, 1917.

8 SHEETS-SHEET 5- I N V EN 0R.

WITNESSES:

L. C. REESE.

MACHINE FOR MOLDING DOUGH AND THE LIKE.

APPLICATION FILED JUNE 19. IQIG.

1,226,251., Patented May15, 1917.

8 SHEETS-SHEET 6.

WITNESS/ES} Z I OR.

L. c. REES MACHINE FOR MOLDING DOUGH AND THE LIKE.

APPLICATION FILED JUNE I9, 1916.

1,296,251 n, Patented May 15, 1917.

B SHEETS-SHEET 7.-

WITNESSES: N2 IN VEN OR.

L. C. REESE.

MACHINE FOR MOLDING DOUGH AND THE LIKE. APPLICATICIN FILED JUNE 19. 1916.

1,,2Q6,251 Patented May 15, 1917;

8 SHEETS-SHEET 8.

Eillillllli u wwIM/I/fi I INVENTOR. WJTNESSES: yg

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"UNITED @TATFE PATENT LOUIS CHARLES REESE, OF SAGINAW, MICHIGAN, ASSIGNOR TO W'ERNER & IFLEIDERER 00., OF SAGINAW, MICHIGAN.

MACHINE FOR MOLDING DOUGH AND THE LIKE.

Specification of Letters Patent.

Patented May 15, 19117.

Original application filed October 2, 1915, Serial No. 53,842. Divided and. this application filed June 19, 1916. Serial No. 104,559.

b all whom it may concern Be it known that I, LOUIS CHARLES Rnnsn, a resident of Saginaw, in the county of Saginaw and State of Michigan, have invented new and useful Improvements in Machines for Molding Dough and the like, of which the following is a specification.

This invention relates to improvements in machines for sheeting, rolling and finally forming pieces of dough into the required shape, ready for the oven; and its object is to accomplish this result in a more efficient and perfect manner than was hitherto possible in this kind of machines. i

I attain these objects by a number of novel and improved devices, mechanisms, arrangements and combinations of parts all of which are fully described on hand of the accompanying drawings specifically produced and in the appended claims.

The main feature of my invention is that in those parts of the machine in which the dough is subjected to considerable pressure, namely in the dough sheeting and loaf forming operation, I make the parts producing the pressure not only adjustable in regard to their distance from each other, but also resilient by simple devices, adapted to regulate the resiliency according to the nature of the dough. In the machines of this kind hitherto constructed the openings through which the pieces of dough are pressed, are in most cases made adjustable, but not resilient, so that the dough is forced through without any chance of redress in case the openings should not be in accordance with the nature of the dough. The consequence is that in such cases the whole quantity or larger portion of the carbonic acid gas which. has been formed in the dough by means of the tedious and costly process of fermentation in order to obtain a light and spongy loaf, is forcibly driven out and must be reproduced therein, before it can be put into the baking oven. In my machine on the contrary, in which in consequence of its resilient devices the dough is not exposed to such a Severe treatment, the carbonic acid-gas contained in same is completely or for the most part retained, and thus a great saving in time and in raw material by the decomposition of which the carbonic acid gas is formed, is effected.

The drawings represent, as example of the application of the invention, a machine for molding bread dough into tin loaves, but of course it will be understood that I do not wish to be limited to this machine specifically, as the invention may be readily adapted and employed with the greatest ease in other machines for molding dough or other plastic material into other shapes and forms.

Figure l is a side elevation of the ma chine showing its various parts and their general arrangement, the upper rollers of the dough sheetin a a Jaratus as well as the bottom-plate of the load forming part of the machine being made resilient by means of weight appliances.

Fig. 2 is a cross section of the device for the adjustment of the upper rollers of the sheeting apparatus.

Fig. 3 represents an arrangement for making the upper rollers of the sheeting apparatus resilient by means of weights, in

longitudinal section, and Fig. 4C is a crosssection of same.

Fig. 5 represents the dough folding apparatus.

Fig. 6 and Fig. 7 are opposite elevations showing the driving arrangement and gearing of the machine at both sides.

Fig. 8 is a section through the arrangement of the inlet and Fig. 9 of the outlet of the loaf-forming apparatus. Fig. 10 is a plan of the latter arrangement.

Fig. 11 is a side elevation of the loafforming apparatus itself of the frame work carrying same, showing the rack arrangement for adjusting the distance between the bottom plate and the face of the reel.

Fig. 12 is a vertical cross-section of the side-adjustment and Fig. 13 a cross-sectional plan of the bottom-adjustment of the bottom pl te,

Fig. 14 is an enlarged section of the bearerbars and guide blocks of the adjustment of the bottom plate.

Fig. 15 is a section vertical to that of Fig. 14; through the side bearer bars and guide-blocks, and Fig. 16 is the same section through the bottom bearer'b'ars' and guide-blocks. T 1

Fig. 17 shows the arrangement of the side guide-blocks, and Fig. 18 that of the bottom guide-blocks of the bottom plate.

Likeletters and like letters with like numerals. addedthereto indicate like. parts in j j .reel I and the statlonary, ad ustable bottom all figures. A is the hopper for feeding the machine.

13,13 B and B are the brake rollers, 'between which the dough is rolled out tosa sheet, and which, together with the bridge plate C, form the sheeting apparatus of the "machine. B and B are called the upper pair, and B .and 13,, the lower. pair of rollers. B andfB form the top, and B and B,, the bottom rollers.

I fAllrollers are rotated in the direction of the dough, that is, downward; therefore B and B revolve in opposite direction to B and The bottom rollers are provided at their sides wlth guide plates, which, to-

' gether with the guide bridge 0, lead the dough from the upper pair to the lower pair of rollers andthen to the folding apparatus ,iof the machine.

Dan'dID. are the devices for adjusting the distance betweenthe top and bottom rollers, D serving -for the upper, and D for the lower pair of rollers.

These devices consist of iguide rods arranged at eachsideof the upper and lower pair of rollers vertically to the sheet of dough and provided with stops on which the guide blocks of the upper rollers rest, and

with screw threads turning in the female threads of screw blocks fixed to or of projections of the-stationary frame work sup; porting the machine.

I The pair of guide rods D are turned simultaneously by the bevel gearing D and D by D -In this way, as all the screw threads and bevel wheels are the same, the rods with their stops and thereby the upper rollers aremoved to the same degree upward T or downward according to the direction in which the bevel-gearing belonging thereto is turned. 'The guide-blocks of the upper rollers are held in position on the stops of the "guide blocks belonging thereto by the weight arrangements E. and .15 respectively. The

"degree of resiliency is changed by decreasing or increasing the weights. used. The completely sheeted piece ofdough passes gradually, as it leaves thesheeting'rollers, to the folding apparatus in order to be formed into a roll. The sheet of dough moves, guided by the upper convex part of the folding gearing of .the machine.

G in accordancewith the size of the piece 7 of dough to be worked, and with that of i the roll to be produced therefrom; The roll of dough is then definitely formed into the required loaf shape in the molding channel formed by the face and sides ofthe rotating I plateHwith the fixed inlet plate K and the adjustable intermediate plate L at the inlet side, and with the adjustable outlet plate M at the outlet side'of the channel.

In order to-regulate tho'size and shape of the cross section of the above described molding channel according to the weight, volume densityjand resiliency of the roll. of-dough to be'formed to loaves therein, the bottom plate H is provided with the lack-devices l\ ,-N and N. (Figall). When adjusted, the bottom plate is keptin its position by the weight arrangement 0., The resiliency of the bottom-plate thus obtained is regulated by adj usting the weight employed.

P is the chute leading the completely molded loaf of dough from the outletls f of the molding channel to the belt conveyor R carrylng it to has destmation.

I In the frame work of the machine S, S and 8, indicate the three pairsof legs of the machine carrying at their inner sides the racks of the bottom plate adjustment, and at the top the. horizontal main frame S Thelatter supports theiaxle of the molding reel I, that of theroller for the belt conveyer R and the side structures S and S carries the hopper A at its top, below same the whole sheeting apparatus, then the folding member F, theaXle of the folding roller .G, the driving gear of the machine and the inlet-plate K. a

S serves as support for the outlet plate M and the chute: P. v j For supporting the grooved pulleys for the rope carrying the weight, 0 to travel over, the side structure S is prolonged, and a cross piece S,,' provided, connecting the upper parts of Stand S i i T is the electric motorfor driving the V represents a flour sprinkler of ordinary construction for dusting the dough when en- ,tering'the machine,

[I am now going to describe the various parts'of the machine, their connection with and position toward each other in a more ranged'at the top ofthe framework S that the dough pieces dropped thereon slip easily without the slightest hindrance between the rollers B and B In the device D, Fig. 2, for adjusting the distance between the rollers B and 13,, the guide rods (Z are provided with the screw threads (Z and held by and turning in the female threads 8 of the projections 8 on the inner sides of the frame S The shaft Z) of the roller B is carried by the bearings 6 arranged on the stationary frame S and the shaft of the roller B rotates in bearings 6 provided in the block Z) sliding on the guides (Z by means of the channels arranged in the block 7), and exactly fittin to the rods (Z. The latter are provided with the stops (Z to carry the movable block 7) and turned by the bevel gearing D The latter consists of the bevel wheels (Z fixed to the end of the guide rods (Z below the screw threads (Z and. engaging with the bevel wheels (Z fixed to the shaft (Z turnable in the frame cl by means of-the hand wheel (Z,. The frame (Z is provided with the bearings (Z arranged between the bevel wheels (Z and the stops (Z, attached to the guide rods (Z, so that, when the hand wheel (Z, is turned, the bevel wheels (Z fixed to the shaft (Z remain in gearing with the bevel wheels (5,, fixed to the guide rodscl, the frame (Z being held in position by the bearings (Z Thus, the guide rods (Z are simultaneously turned in the latter and moved up and down by means of the screw threads (Z and 8,, lifting or lowering the block 6 carrying the upper roller 13,, at both ends at the same time and to the same degree.

The blocks carrying the upper rollers are kept in their position on the stops (Z (Fig. 1, F ig. 3, and Fig. 4) by means of the weights E and E carried by steel wires 0 fixed to same by means of the hooks 6 These wires 0 (Fig. 4) run along each side of the rollers B and B over the grooved wheels a, turning around the cross bar e fixed by means of the supports 8 to the stationary framework S of the machine, and are fastened by means of the hooks b to the sides of the movable block 6 carrying the upper roller B The rollers B and B are provided at their sides with the circular plates 7),, respectively 6,, reaching over the lower part of the rollers B respectively B for preventing the sheet of dough from becoming broader than the rollers.

The lower pair of rollers B and B, are equipped withthe adjusting devices D and the weight appliance E which are constructed in their details and work exactly as those devices employed for the upper pair of rollers B and B The straight steel plate C, Fig. 1, is fixed to the framework S, of the machine and constructed of such a shape as to lead the dough treated in the rollers B and B from between the side plates 6, to the rollers B and B in between the side plates 6 of the roller B The shaft b, of the roller B turns in the bearings Z2 (Fig. 1) arranged at the stationary framework 8,, and the shaft 1),, of the roller B in the bearings 6 carried by the movable block o sliding on the guide rods of the adjusting devices D The upper part f of the folding member F is shaped to receive the dough from the rollers B and B and must therefore fit between the side plates b of the roller B while the lower curved part 7, of F has the width of the folding roller G.

The folding member F is attached to the frame S by means of the screw studs f and f, provided at each side of F. For adjusting the position of the latter, the slots 8 and s, are provided at each side of the frame S, for the studs f and f In order to fix the plate F in its adjusted position, it is clamped to its supports S by any known means, for instance screw nuts fitting over the threaded ends of the studs f andv f, protruding outside the supports 5,, and pressing against same.

The folding roller G rotates preferably quicker than the sheeting rollers B and B, and has preferably a corrugated surface. =Its shaft 9 turns in bearings 9 carried by the framework S,.

The electric motor T drives by means of the belt 25 the main pulley if, fixed to the main shaft t rotating in bearings t, arranged in the framework S. (Figs. 6 and 7) On that end which carries the driving pulley t, (Fig. 6), the driving shaft 6 is provided with the gear wheel 25 which mesh-es with the gear wheel b fixed to the shaft 7),, of the roller B which is thus rotated; t also meshes with the idler t rotating around the lug 25, arranged at the framework S and meshing with the gear wheel 9 fixed to the shaft 5], and thus drives the roller G. The gear wheel Z2 meshes with the idler Z, rotating around the lug t fixed to the framework S and, meshing with the gear wheel o arranged at the shaft 5, drives the roller B.

In Fig. 6 the gear wheel 9 driving the folding roller G is shown as being of half the size as the gear wheel Z2 driving the roller B and, both being drivenb directly and through the idler t -by means of the gear wheel t fixed to the main driving shaft of the machine, the folding roller G rotates with double the velocity as the sheeting roller B does.

On the opposite side of the driving pulley t, (Fig. 7) the driving shaft 15 carries the sprocket wheel t. which by means of the chain i drives the sprocket wheel 6 attached to the shaft 6 and thus the roller 13,,

G carries the sprocket wheel 25,, which by means of the chain drives the sprocket wheel 6 fixed to the shaft 6 and thereby the roller 13,. r

The reel I consists of the ring 2' the face of which is indicated by the letter i,, and the two sides 2', of the rim. The ring 1' is supported by the spokes 2', and the crown i fixed on the axle i passing through the center of i. The axle i revolves in bearings i arranged at the horizontal framework S of the machine. The reel I is rotated by means of the gear wheel i, fixed to the axle i and meshing with the idler t rotating around the lug 1' fixed to the frame S and meshing with the gear wheel attached to the driving shaft Z; of the machine on the side opposite to the driving pulley, (Fig. 7

The bottom plate H fits loosely into the channel formed by the face i, and the sides a, of the reel I and, following in outline the circumference of the lower half of the lat ter, is the stationary bottom of the molding or loaf shaping channel of the machine. At the inlet side for the dough to the channel the bottom plate H is connected by means of the cross bar it with the intermediate plate L made of thin flexible steel, and at the outlet side for the dough from the channel, by means of the cross bar li with the outlet plate M made of the same material as L. (Fig. 8 and Fig. 9).

The inlet plate K has nearly the width I of the molding channel, fitting loosely into the same, and is curved following the circumference of the reel; it is fixed to the framework S by means of the screw studs and 7;, arranged at each side of the plate, (Fig. 8).

The inlet plate K ends in the knife-like edge 70, between which and the cross bar Z arranged at the framework 8, the intermediate plate L is able to slide, following the movements of the bottom plate H. The

cross bar Z is provided with the lugs Z nearly touching the rim i, of the reel, in order to prevent any side slip of the plate L. Fig. 8 shows the latter and the bottom plate in two different positions fully explaining the working of the arrangement just described.

The rack devices (Fig. 11) N and N serve to adjust the sides, and the rack device N the lowest point of the bottom plate H. The guide blocks a are the same for all these devices, while the bearer bars a, which with the guide blocks n form the immediate support of the bottom plate H, differ from each other, the bars a, belonging to the side devices N and N being provided with slots at, (Fig. 15) to give some play to the guide rods 1%, of the guide blocks a, while the bearer bar a, belonging to the bottom device has closely fitting openings a, (Fig. 16) in which the guide rod's n move like in a stufiing box.

The guide rods n for the sides of the bottom plate H are horizontal and slide in slots giving vertical play, while those arranged at the lowest point of H are vertical and slide in tight vertical openings. The guide rods 9%, are provided with stop plates 7, (Fig. 14) against which the bearer bars n are pressed by the weight arrangement 0.

The bearer bars n, employed at the sides of the bottom plate H are fixed at one end to the sliding rack blocks a and at the other end to the sliding rack blocks 91,. The rack blocks a and a, move in channels formed by the back blocks 12,, and a securely fastened to the legs S, respectively 8,, of the framework of the machine, and by the stop blocks a and 11 These channels slant upward toward the bottom plate H, so that, when the rack blocks are moved in the channels upward and toward the bottom plate H, the latter is lifted while its distance from the face 2', of the reel I is diminished, and that, when the rack blocks are moved downward and away from the bottom plate H,

the latter is lowered, while the distance between same and the face '5 is increased.

The angle which the line in which the rack blocks move, forms with the horizontal line, is a function of the diameter of the cir cle the bottom plate is part of, and of the required limits of its adjustment in regard to the face 2', of the reel I.

In Fig. 11 for instance the racks N, N, and N and their gearing have been so arranged that all the points of'the bottom plate H are at any position thereof equally distant from the face 2', of the reel I. When the plate H standing at its lowest point, the

limit farthest away from the face of the reel, is lifted by means of the rack N vertically upward to its highest point, the limit nearest to the face of the reel, the sides of the plate H must be moved the same amount toward the face of the reel, and therefore the racks N and N must compress these sides- N at the outlet and N at the inlet of the molding channelthis same distance. By these lifting and compressing movements of the plate H the diameter of the circle of which it forms a half, and the center of which is identical with the center of the reel I, is shortened by double the length of the distance for which the plate H was moved toward the face of the reel, that is double the distance of the limits of its possible adjustments. Thus, each top point of the half circle of the plate H is lifted above its horizontal center-line a distance equal to one fourth of the difference of the circumferences of the two circles of which the plate H at its position nearest to and at its position farthest away from the face 2', of the reel I is a part. The angle which the racks Nand N moving the sides of the bottom plate H, make with the horizontal, is therefore in this example equal to the angle formed by the hypotenuse and the horizontal base of a right-angled triangle, the length of the base being equal to the difference of the limits of the possible adjustments of the plate H and the length of the upright of this triangle be: ing equal to one fourth of the difference of the circumferences of two circles the diameters of which are those of the plate H when at the limit nearest to and at the limit farthest away from the face '5 of the reel I.

The teeth 92 and a of the rack blocks a and a, mesh with the teeth of the pinions n and a fixed to the common shaft 97. on one side and the common shaft n on the opposite side of the bottom plate H. These shafts are rotated in bearings n and H arranged in the legs S and S of the framework of the machine, and bear at the part situated outside the same, bevel wheels a and n meshing with the bevel wheels H and m both of which are fixed to the shaft 91 turned by means of the hand wheel 92 in bearings carried by brackets n fixed to the legs S and S of the machine. The bevel wheels a and 02 are arranged on the shaft a in such a manner that they work in 0pposite direction to each other, turning the pair of pinions 71 and a situated at one side of the bottom plate H in opposite direction to the other pair situated atthe opposite side; thus, the sides of the bottom plate H are moved to or from its center and lifted at the same time by simply turning the hand wheel n The bearer bar n holding the lowest point of the bottom plate H, is fixed to the pair of rack blocks a sliding in a vertical direction in the channels formed by the back blocks a and the stop blocks n The back blocks a are attached to the center legs S of the machine. The teeth a of the rack blocks a mesh with the pinions a fixed to the common shaft 92 which turns in the bearings n arranged in the legs S of the framework of the machine, and carries at the same side of the latter at which the shaft w and hand wheel n are attached, the bevel wheel n meshing with the bevel wheel n fixed to the shaft w turning in bearings of the supports a attached to the legs S and S of the machine. The shaft 11. is provided at its upper end with the bevel wheel n meshing with the bevel wheel n fixed to the shaft n so that by turning the hand wheel w also these bevel wheels and pinions are moved, and thereby the bottom bearer bar a and the lowest point of the bottom plate H are adjusted in a vertical direction.

In the construction shown in the drawings, the bevel wheels a 11 a a a n a and n are arranged so that the shafts a 12 and 71 they simultaneously drive when the hand wheel is turned, revolve with exactly the same velocity, and the size of the two side pairs of pinions w and 72 fixed to the shafts a and 71 is such in proportion to that of the bottom pair of pinions 77/ fixed to the shaft 12 that by means of the racks m, and n, the two bearer bars a, of the side adjustments N and N and thereby the sides of the bottom plate H are moved in relation to the face 71 of the reel I to the same degree as by means of the racks a the bearer bar a, of the bottom adjustment N and thereby the lowestpoint of the plate H. In this way the distance between the face i of the reel I and the bottom plate H remains the same at all points at any po sition of the latter.

If it is desired that this distance can be adjusted differently at different points, then the above named bevel wheels and pinions must be constructed and arranged accordingly. In the weight arrz'ingeinent O keeping the bottom plate H in position by pressing it with the guide blocks a and the stops a against the bearer bars 91 two wires 0 pass underneath the bottom plate H along each side of same in the ruts n (Fig. it provided in the guide blocks 11; at one side of the machine the two wires travel upward over the grooved pulleys 0 and 0 and then downward, where the ends are connected to the pair of hooks 0 arranged at the sides of the top of the weight 0 and at the other side of the machine the two wires run over the grooved rolls 0, and 0 -and are fastened to the pair of hooks 0 at the top of the weight 0. The resiliency of the bottom plate H is regulated by adjusting the weight 0.

In this arrangement the middle part connecting the two guide rods w of the guide blocks a is a simple straight bar as is also the middle part of the bearer bars m (Fig. 14

The outlet plate M (Fig. 9 and Fig. 10) connected by the crosspiece h, to the bottom plate H as already mentioned above, has an upward pointing part at which forms the end part of the molding channel, and is bent over at the top m for the ready molded loaf of dough to slip easily over same onto the outlet chute P. At its upper part the outlet plate M is provided with two studs m carrying the cross bar m, sliding in the slots 8 arranged in the framework S This cross bar 172 supports two hinges 2) attached to the outlet chute P which consists of a straight iron plate provided at each side with a rim 79 to guide the dough loaf onto the conveyer R. The chute is provided at its under side with brackets 72 carrying the cross bar 79 sliding into slots 8 arranged in the framework S By means of the rod on, and the slots 8 the top m, of the outlet plate M is always kept in its proper position above the chute P while moving upward and downward with the bottom. plate H the chute P following these movements at the same time.

The roller 1" of the belt conveyer R (Fig.6) rotates around its axle 1, running in bearings 0",, provided on the horizontal part S of the framework, and is driven by means of the sprocket wheel '1', attached to the axle 9",, and the chain from the sprocket wheel i fixed to the axle i of the reel I.

For operating the machine, at first the different parts of the same must be adjusted according to the weight, size and qualities of the pieces of dough to be molded and to the size and shape of the ready molded loaf to be obtained from the piece of dough placed in the machine. In the machine shown in the drawings the distance of the two pairs of rollers, B and B and B and 13,, are regulated by turning the hand wheel (Z, belonging to their adjustment arrangements, and the resiliency of the upper rollers 13, and B is adjusted by altering the weights E and E The folding member F is adjusted by means of the screws 7, and f,. The side of the molding channel is regulated by turning the hand wheel m and the resiliency of the bottom plate H by regulating the weight 0. V

The pieces of dough to be shaped into loaves are then placed, one after the other, into the hopper A, from which they enter the sheeting apparatus; they are rolled out to a sheet between the rollers B and B and B and 13,; the resulting sheets are folded up into cylindrical rolls by means of the folding roller G and folding member F and pass then over the inlet plate K into the funnel like passage formed by the lower part of the plate K and the intermediate plate L with the face 2', of the rotating reel I, and from there into the molding channel proper formed by the latter and the stationary resilient bottom plate II] The readyshaped loaves of dough leave then through the upper part of the molding channel formed by the face 2', of the reel and the outlet plate M and drop over the top m, of the latter onto the chute P and the conveyer R which takes them to their destination.

I claim: 1. In a dough molding machine, comprising rotary adjustable rollers adapted to roll out the dough to a sheet, means consisting of screw rods with stops and bevel gearing for adjusting the distance between each pair of such rollers, resilient means consisting of weights for keeping this distance, a curved adjustable folding member, a folding roller revolving'toward the concavity of the foldlng member and quicker than the sheeting rollers, and arranged so in regard to the latter and to the folding member that the sheet of dough coming from the former is driven into the concavity of the latter and thus rolled up, a rotary reel, a plate fitting loosely between the sides of the reel and forming with its face and sides the molding channel, means consisting of racks for adjusting the distance of this plate from the face of the reel, and resilient means consisting of weights for keeping this distance.

2. A dough molding machine, comprising a feed hopper, rotary rollers arranged in pairs and adapted to roll out the dough fed thereto into a sheet, a stationary frame carrying the lower set of rollers, movable blocks for each roller belonging to the upper set, guide rods adapted for these blocks to slide onand adjustably arranged at the said stationary frame, stops provided on the guide rods to hold the movable blocks,

weights connected to these blocks and pressing them against thesaid stops, stationary plates leading the dough sheet from one pair of rollers to the successive one, a curved plate situated underneath the last pair of rollers, a roller adjacent to this plate and rotating toward its concavity and quicker than the sheeting rollers, thus folding up the sheet into a roll, a stationary curved plate. adapted to lead'the rolls of dough produced into'the final molding channel,

a rotary reel, a bottom plate fitting into the annularchannel and, following the lower half of its circumference, forming with it the molding channel, a flexible plate fixed thereto andsliding behind the plate leading the dough into the channel, guide rods arranged at the bottom plate of the molding channel, pointing outward and provided with stops, bars provided with openings for the said guide rods to slide in, racks carrying the said bars, pinions working the racks, bevel gearing working the pinions simultaneously, a weight, wires carrying same,

running along, the outside of the bottom plate of the molding channel and so arranged as to press the stops of the said guide rods against the bars in the openings.

of which these rods slide, a flexible plate fixed to the bottom plate of the, molding channel at its outlet end and having a turned over top, and a chute receivingthe completel molded dough loaves from over the top o the latter plate and movably connected to'same, both plates being provided with means to follow together the movements of the bottom plateof the molding channel. 7

3. A dough molding machine comprising the feed hopper A, the brake rollers B, 13 ,13

and E the bridge plate C, the adjustment rack adjustment devices N, N, and N the devices D and D the level gearlngs D and Weight arrangement 0 and the chute P, sub- D Working the said devices, the Weight arstantially as shown and described.

rangements E and E the folding member LOUIS CHARLES REESE F, the folding roller G, the rotary reel I, WVitnesses:

the bottom plate H, the inlet plate K, the EMELIE M. ANDRE,

intermediate plate L, the outlet plate M, the JEAN N IESSEN.

Copies of this patent may be obtained for five cents each, by addressing the Commissioner of Patents, -\Jll'ashington, D. C. 

